DE4309422C1 - Data transmission - Google Patents

Abstract

A method and a device for transmitting data between a fixed station and a station (1) located in a vehicle with a first reception channel (2) has a second reception channel (3). The received data are processed simultaneously in both reception channels. This enables identification of the reception channel for which the data are designated. The designated reception channel forwards the data which it receives without delay. The non-designated reception channel suppresses the data which it receives. <IMAGE>

Description

The invention relates to a method for transmission of data between a fixed station and one station located in a vehicle and a device for performing the method.

The exchange of data between a vehicle and has a fixed station especially for the public transport increasingly important won. Through such a data exchange can, for example, a vehicle-autonomous location detection without the participation of the driver.  

An infrared transmission system is used to record the location known, which from vehicle beacons and local beacons exist. The local beacon sends during the pre crossing of the vehicle their location code with addition formations received by the vehicle beacon conditions and evaluated in the on-board computer.

The on-board computers are supplied with data manually via portable computers. Should the data of the on-board rake ner to be changed, the portable computer with the On-board computer are coupled, whereupon the Data can be transferred. The effort for that Change the data of on-board computers, for example in the event of a timetable change, therefore, is of course pregnant.

A supply of the on-board computer using the known Transmission system differs because of the large amount of the data to be transferred, since the known Systems have a low data transfer rate. A vehicle would have to do so during the required Stop time at a location beacon to get a data out to enable exchange.

It is an object of the invention to transfer data to improve in a system mentioned at the beginning, being compatible with existing systems must be guaranteed.

The solution to this problem arises from the kenn drawing part of claim 1 and the claim 9.  

By training those in the vehicle Station with a second connected in parallel Receive channel can be from the fixed station sent data from both channels simultaneously be received. By receiving the Data can do this according to how it works of the channels are evaluated. A channel will look like this placed that he had data from a fixed station which can receive their data with a high Data transmission rate sends, and the other channel like this designed to receive data from a fixed station which can receive their data with a low transmits its data transfer rate, only that delivers Data usable at its output, which to the Station of the fixed station is adapted, the other channel delivers indefinable at its output Signals. Depending on the fixed station he therefore one only holds at the exit of the adapted Channel a usable information. The information is already available at the time as it is at a station in a vehicle would have been available, which only for one stationary station would be compatible.

If the vehicle comes to a fixed station, wel designed for a different data transfer rate is than that previously described, the other delivers right channel at its output useful data, gene the first-mentioned channel indefinable signals delivers at its exit.

Depending on the channel, what usable data data will be prepared accordingly agreed, adapted to the respective fixed station sender of the station in the vehicle sends.  

With the inventive method or the device according to the invention it is possible Data from various fixed stations are sent with different data rates received and processed without delay. Hereby is the station in a vehicle stationary stations with different data about transmission rates fully compatible. So it can next to the existing system with its slow Data transmission speed built up a system be, its data exchange with a much higher Data transfer rate takes place. This is it possible, for example automatic control of passenger information devices, an automatic Control of the validator, an exact display of the driving flatness (for example delays), the control of departure signals at stops as well as a driving Autonomous light signal influencing without the co-workers the driver.

Advantageous developments of the invention result itself from the subclaims.

By using different modulations will be the separation between the two channels improved. The danger of mutual interference solution of the two channels is different Modulation types reduced. If a channel with Fre frequency modulation and the other channel with Amplitude modulation, so you get next to the advantage a safe separation has the further advantage that on standard components of entertainment electronics nik or telecommunications can be gripped.  

By using two transmission channels, which who operate with different types of modulation the same can be reached on the sending side share like on the reception side. Although it is special is advantageous with frequency and amplitude modules other modulation types ten, such as pulse code modulation or Pulse phase modulation can be used. Both channels can also be operated with the same type of modulation be.

By transferring the data between the stations A system is possible using infrared light to build up, in which the stationary stations spatially are not far apart, but the not yet influence each other. By an ent speaking choice of beam angle and setting the direction of radiation can have a mutual influence almost completely excluded. A If necessary, residual influence can be seen which are turned off.

Although the transfer of data between the Statio is particularly advantageous by means of infrared light, can also use ultrasound or high frequency are transmitted.

The outputs of the demodulators are with an evaluator teschaltung connected. In the evaluation circuit determined which channel received valid data Has. Depending on the reception channel determined in this way the subsequent processing is determined.  

By determining a transmission channel in dependent of the specific receiving channel can be transmitted te of the station in the vehicle if adapted to a different data transfer rate become. It is therefore possible that the transmitter with the sends the same data transfer rate as the recipient received data. It is also possible to go through additional information received the selection of the to influence certain transmission channel.

Through the invention, a teaching for fast He know a transmission path without data loss Provided. Although the invention together hang with a station in the vehicle was written, it also applies to a stationary one Station. That means also the fixed stations can be formed according to the invention. Or both Stations can be formed according to the invention.

More details, features and advantages of the before lying invention emerge from the follow the description of a particular embodiment game with reference to the drawing.

The only figure shows a block diagram of a station in a vehicle for the data transmission according to the invention.

In station 1 there are two reception channels 2 and 3 as well as two transmission channels 4 and 5 . The receiving channels 2 , 3 are connected in parallel and receive their signals from an infrared receiver 7 . The signals received by the infrared receiver 7 arrive next via band filters 11 and 12 . The band filter 11 of the input channel 2 is designed for a center frequency of 48 kHz and forwards its signal to an AM demodulator. The bandpass filter 12 of the input channel 3 is laid out at a center frequency of 900 kHz and passes its signal on to an FM demodulator 10 . The outputs of the demodulators 9 and 10 each have a separate input (R1, R2) of a serial interface module (DNSC, Dual Multi protocol Serial Controller). This can receive on both inputs (R1, R2) at the same time.

If the vehicle drives past a conventional stationary station, the infrared receiver 7 receives a slow IR signal which is transmitted with a carrier frequency of 48 kHz and is amplitude modulated. The signal can pass through the band filter 11 and is demodulated by the demodulator 9 . The band filter 12 of the input channel 3 forms a block for the received signal. In addition, the FM demodulator 10 cannot process the amplitude-modulated signal. At the output of the FM demodulator 10 thus all if indefinable signals arise, whereas at the output of the AM demodulator 9 the NF contained in the received signal, that is to say in this case the transmitted data, are available.

Thus, the input (R1) of the serial interface module 13 does not receive any usable signals, whereas the input (R2) receives evaluable signals. The interface module 13 recognizes whether it is a conventional, that is to say slow, data transfer rate or whether it is a new, that is to say fast, data transfer rate. Depending on the received data transfer rate, the data transfer rate to be sent and the modulator are set. The interface module 13 outputs a fast data transfer rate on its output T1, whereas it outputs a slow data transfer rate on its output T2. The outputs T1 and T2 are connected to transmission channels 4 and 5 , which are connected to a modulator 8 . Depending on the received data transfer rate, the interface module 13 emits a signal to the modulator 8 , whereupon the modulator 8 adjusts to FM or AM modulation. The output of the modulator 8 is connected to an infrared transmitter 6 .

Since the data are to be transmitted in full duplex mode, the filters 11 and 12 are correspondingly narrow-band.

The serial interface module 13 outputs the received data in parallel to its output. The data output is processed in a conventional manner.

Claims (13)

1. Method for transmitting data between a stationary station and a station ( 1 ) located in a vehicle with a first receiving channel ( 2 ),
characterized in that

• - At least one second receiving channel ( 3 ) is provided, and
• - the received data are processed simultaneously in the receiving channels ( 2 , 3 ),
• - It is determined for which reception channel ( 2 or 3 ) the received data is intended, and
• - Whereupon the specific receiving channel ( 2 or 3 ) forwards the data already received by it and the non-determined receiving channel ( 3 or 2 ) suppresses the data received by it.

2. The method according to claim 1, characterized in that the receiving channels ( 2 , 3 ) differ in the type of modulation. 3. The method according to claim 1 or 2, characterized in that at least one receiving channel ( 2 ) works with frequency modulation and at least one receiving channel ( 3 ) works with amplitude modulation. 4. The method according to any one of claims 1 to 3, characterized in that two transmission channels ( 4 , 5 ) are provided which differ in the type of modulation. 5. The method according to claim 4, characterized in that at least one transmission channel ( 4 ) works with frequency modulation and at least one transmission channel ( 5 ) works with amplitude modulation. 6. The method according to any one of claims 1 to 5, characterized, that the data between the stations by means of infrared light transmitted. 7. The method according to any one of claims 1 to 6, characterized in that the subsequent further processing is determined depending on the specific receiving channel ( 2 , 3 ). 8. The method according to any one of claims 1 to 7, characterized in that a transmission channel ( 4 , 5 ) is determined as a function of the specific receiving channel ( 2 , 3 ). 9. Device for carrying out the method according to one of claims 1 to 8, with a transmitter ( 6 ), which is connected to a modulator ( 8 ), and a receiver ( 7 ), which is connected to a first demodulator ( 9 ), characterized in that at least one further demodulator ( 10 ) is provided, which is parallel to the first demodulator ( 9 )
is connected, the inputs of the demodulators ( 9, 10 ) being connected to the receiver ( 7 ), and an evaluation circuit ( 13 ) being provided which is connected to the outputs of the demodulators ( 9, 10 ) and forwards the data of a demodulator . 10. The device according to claim 9, characterized in that band filters ( 11, 12 ) are provided, which are connected between the receiver ( 7 ) and the inputs of the demodulators ( 9, 10 ). 11. The device according to claim 9 or 10, characterized in that the first demodulator ( 9 ) is an AM demodulator and the further demodulator ( 10 ) is an FM demodulator. 12. Device according to one of claims 9 to 11, characterized in that the transmitter ( 6 ) and the receiver ( 7 ) are infrared components. 13. The device according to one of claims 9 to 12, characterized, that the modulator can be switched to AM or FM, the switching depending on the received Signal occurs.